WO2015104269A1

WO2015104269A1 - Assembly for storing electrical energy, and associated production method

Info

Publication number: WO2015104269A1
Application number: PCT/EP2015/050119
Authority: WO
Inventors: Erwan Vigneras
Original assignee: Blue Solutions
Priority date: 2014-01-07
Filing date: 2015-01-06
Publication date: 2015-07-16
Also published as: EP3092655A1; FR3016241A1; US20160336567A1

Abstract

The invention relates to an assembly for storing electrical energy (10) comprising a storage element (16) comprising at least one elementary cell (18) comprising first and second electrode complexes (19, 20) stacked in a stacking direction (21), said elementary cell further comprising a first separator (26) made of a plastic material extending between the first and second electrode complexes, and an outer shell (11) receiving the storage element (16), the shell comprising two separate surfaces (15, 14) forming electrical terminals of the assembly having opposite polarities, the one or more first complexes (19) being electrically connected to a first terminal (15) and the one or more second complexes (20) being electrically connected to a second terminal (14), in which the element comprises at least one additional layer (29, 30) extending at least at one end (31, 32) of the storage element in the stacking direction, each additional layer being made up of a component identical to one of the components of the elementary cell (18), none of the additional layers of a single end of the storage element being connected to the terminal having the opposite polarity to the terminal to which the electrode complex adjacent to said additional layers is connected.

Description

ELECTRIC ENERGY STORAGE ASSEMBLY, AND METHOD OF

ASSOCIATED MANUFACTURING

GENERAL TECHNICAL FIELD

The present invention relates to an electrical energy storage assembly, and a method of manufacturing such an assembly.

More particularly, the present invention relates to an electrical energy storage assembly having a plastic separator layer.

STATE OF THE ART

It is known from the state of the art of electrical energy storage elements such as supercapacitors or batteries.

Such an electrical energy storage element generally comprises two electrodes of opposite polarity, porous and impregnated with electrolyte, between which is disposed an insulating and porous layer called "separator". The separator layer is used to isolate the electrodes from each other so as to avoid short circuits, while ensuring the ionic conduction between the electrodes.

In a supercapacitor, ions move under the effect of an electric field to or from the surface of the electrodes depending on the state of charge or discharge of the supercapacitor.

In a battery, the ions move from one electrode to another depending on the state of charge or discharge of the battery under the effect of chemical reactions taking place at each of the electrodes.

The use of plastic separators is often preferred over the use of paper separators. Indeed, the use of such separators made of polymer not only makes it possible to obtain a storage element having a better resistance to aging, but also to use the storage element at a higher electrical voltage. The use of such separators also makes it possible to reduce the risk of perforation of said separators which can cause electrical contact of two adjacent electrodes of opposite polarity, and therefore a short circuit in the storage element, and also reduce the manufacturing costs of a storage element.

The storage elements as described above are generally placed in a rigid outer casing having a housing and at least one cover closing the housing to form a storage assembly.

However, the manufacture of a storage assembly as described above requires one or more heating steps that can bring the storage element to high temperatures. Such steps are for example the polymerization step of the adhesive used to connect the lid and the housing forming the envelope accommodating the storage element, the dehydration step of the storage element in order to reduce the impurities present. in the electrolyte whose electrodes are impregnated, or the soldering step for electrically connecting each of the electrodes to the terminals of the envelope accommodating the storage element, during which the storage element can be carried up to temperatures of about 180 ° C.

These heating steps often result in an increase in the temperature of the separator by thermal conduction, and it happens that this temperature reaches a value such that it causes a deformation of the separator called "shrinkage", because of the fairly high porosity of the separator, and tending to discover the electrodes at their ends. Indeed, the temperature at which the polymer separator undergoes a large shrinkage is around 130 ° C, especially when the separator is made of polypropylene. Such shrinkage of the separator is particularly problematic insofar as it can lead to an electrical contact of two adjacent electrodes of opposite polarity, and therefore to a short circuit in the storage element. PRESENTATION OF THE INVENTION An object of the present invention is therefore to propose an electrical energy storage assembly comprising at least one plastic separator layer making it possible to avoid shrinkage of the separator when heating the storage element, while retaining the benefits of using the plastic separator.

More specifically, the subject of the invention is an electrical energy storage assembly comprising:

an electrical energy storage element comprising at least one elementary cell comprising a first and a second electrode complex superimposed in a superposition direction, said elementary cell further comprising a first plastic separator, in particular made of polypropylene, extending between the first and the second electrode complex,

an outer envelope accommodating the storage element, the envelope comprising two distinct electrical terminal surfaces of the assembly and having an opposite polarity, the first complex or complexes being electrically connected to a first terminal and the second complex or complexes being connected electrically to a second terminal,

the assembly being characterized in that the element comprises at least one additional layer extending at least one end of the storage element in the direction of superposition, each additional layer being constituted by a component identical to one components of the elementary cell, none of the additional layers of the same end of the storage element being connected to the terminal of polarity opposite to the terminal to which is connected the electrode complex adjacent to said additional layers. It has been realized that the necking problem stated above occurred mainly at the ends of the storage element, the separators located in the core of the storage element being not or only slightly affected by this problem because they are isolated from outside by the electrode complexes between which they are placed. By placing one or more additional layers which do not risk being short-circuited with the electrode complexes which make it possible to store energy (those of the elementary cells), the separator is thus better isolated from the outside. each elementary cell, even those located in the extreme elementary cells, and thus prevents the shrinkage of the elementary cell separator: the additional layer (s) serve indeed as a heat shield and make it possible, by their presence, to reduce the quantity of heat transmitted to the separator of the elementary cell closest to the end of the stack.

Thus, it is possible to use the method of manufacturing the storage assembly of the state of the art without substantially modifying it and the adaptation carried out is neither very expensive (we are simply adding layers that we have already at our disposal and are therefore not specifically manufactured for the occasion) nor very complex to implement.

With an assembly according to the invention, it will be possible even if necessary to use temperatures higher than those of the state of the art during the manufacture of the assembly, according to the needs, thus reducing the time and potentially the cost of the process. Manufacturing. The assembly also makes it possible to widen the range of the polymers that can be used as separator, since the melting temperature is no longer such a strong constraint, to use the polymer whose properties are optimal relative to the desired use.

Thanks to the invention, it is therefore possible to produce a functional energy storage assembly with a plastic separator and using a simple and inexpensive method, without having to adapt the process or the mechanical parts. (envelope, etc.) already used to make the whole. According to one embodiment of the invention, the or at least one additional layer comprises an electrode. The porosity of the electrode makes it possible to trap air in large quantities and thus to produce a very efficient heat shield.

According to one embodiment of the invention, the or at least one of the elementary cells is provided with at least one collector for connecting an electrode complex of the cell to the corresponding terminal, the or at least one one of the additional layers having a collector. The collector may be part of the electrode complex but it may also be a component independent of the electrode.

In particular, the or at least one of the additional layers is an electrode complex comprising at least one electrode and an integral collector.

According to one embodiment of the invention, the or at least one of the additional layers comprises a plastic separator, the additional layers then being inexpensive.

According to one embodiment of the invention, the storage element comprises at least one of its ends three adjacent additional layers formed of two layers comprising an electrode between which a separator layer is interposed.

According to one embodiment of the invention, at least one end of the element, at least one additional layer comprising an electrode is connected to the terminal of the same polarity as the electrode complex adjacent to the additional layers of said end. In this case, there is no risk of a short circuit.

According to one embodiment of the invention, an additional layer of one of the ends is connected neither to the first nor the second terminal, the additional layer is of the separator, collector or electrode type. There is no risk of a short circuit either. According to one embodiment of the invention, the components of the elementary cell or cells form stacked flat layers, the additional layer or layers being placed at one and / or the other end of the stack.

According to another embodiment of the invention, the components of the elementary cell or cells are wound so that the same component forms a plurality of layers of the winding and the element is generally cylindrical in shape, the the additional layers being placed inside and / or outside the winding.

The additional layer located furthest inside the coil is a layer comprising an electrode and / or a collector, which makes it possible to prevent the innermost layer of the coil from sticking to the pin of the coil. winding, as would have been the case if this layer had been a plastic separator.

In particular, at least one of the additional layers is made using a component which also forms at least one layer of the cell or at least one of the elementary cells, which makes it possible to form the additional layers so as to form very simple and economical. This configuration is particularly applicable when the element is wound.

According to one embodiment of the invention, the envelope comprises a housing and at least one cover closing the housing, the terminal surfaces being arranged on two separate parts, the parts being preferably connected with the interposition of an electrically insulating joint. .

The previously described embodiments may advantageously be combined.

The subject of the invention is also a method of manufacturing an electrical energy storage assembly, in particular so as to form an assembly as previously described, comprising the steps of: superposition of a first electrode complex, a first separator, and a second electrode complex in a superposition direction, so as to form an elementary cell;

- Realization of the storage element from at least one elementary cell and at least one additional layer consisting of a component identical to one of the components of the elementary cell, so that the additional layer or layers are placed at the end of the storage element;

placing the storage element in an outer envelope and electrically connecting the storage element to electrical terminals of opposite polarity of the storage assembly, formed by two distinct surfaces of the envelope, so that the first complex or complexes are electrically connected to a first terminal and the second complex or complexes are connected to a second terminal and none of the additional layers at one end of the storage element are connected to the opposite polarity terminal to the polarity terminal to which the electrode complex adjacent to said additional layers is connected.

It will be noted that, during the step of producing the storage element, it is possible to first set up the various elementary cells and then add the additional layers to the end or ends of the stack. Alternatively, the additional layers can be put in place first, at least at one end of the stack, before setting up the components of the elementary cells. Additional layers and elementary cells could also be formed simultaneously.

According to a first embodiment of the invention, the method comprises the steps of:

superposition of a second separator on the second electrode complex in the superposition direction, so as to form an elementary sequence; winding the elementary sequence around a winding axis, so that the storage element has a coil shape.

According to the first embodiment of the invention, a part of the components of the elementary sequence is preferably wound alone around the winding axis, so as to form a core of at least one additional layer around which the sequence Elemental is then rolled up. Advantageously, said one or one of said components comprises an electrode. Advantageously, the first electrode complex and the first separator are wound alone around the winding axis, so as to form the core of at least one additional layer.

According to the first embodiment of the invention, at the other end of the element, a part of the components of the elementary sequence is wound alone around the winding axis, so as to envelop at least one additional layer the coil comprising the elementary sequence. Advantageously, the second electrode complex and the second separator layer are wound alone around the winding axis so as to wrap the coil with at least one additional layer.

According to a second embodiment of the invention, the method comprises the steps of:

superposition of a second separator on the second electrode complex in a stacking direction coincident with the superposition direction, so as to form an elementary sequence;

stacking of several elementary sequences according to the stacking direction;

- Stacking at least one additional layer with at least one elementary sequence, so that the additional layer or layers are at at least one end of the previously formed stack in the stacking direction. PRESENTATION OF FIGURES

Other features, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and should be read with reference to the appended drawings, in which:

FIG. 1 represents an exploded view of an electrical energy storage assembly comprising an electrical energy storage element according to an embodiment of the invention in which the storage element is said to be "wound";

FIG. 2 represents a schematic view of an elementary sequence of an electrical energy storage element;

- Figure 3 shows a schematic sectional view of the wound storage element shown in Figure 1;

- Figure 4 shows a schematic view of an electrical energy storage element according to another embodiment of the invention than that shown in Figures 1 and 3, wherein the storage element is said "stacked".

DETAILED DESCRIPTION

Figure 1 shows an electrical energy storage assembly 10 according to one embodiment of the invention.

The storage assembly 10 includes an outer casing 11. In the example shown in Figure 1, the outer casing 1 1 is substantially cylindrical and extends along a longitudinal axis 12. The outer casing 1 1 comprises a casing 13 provided with a side wall and a bottom 14 disposed at a first end of the housing 13 along the longitudinal axis 12 and open at a second end opposite the bottom 14. The outer casing 1 1 further comprises a lid 15 attached to the second end of the housing 13 to close the open end of the housing 13. The cover 15 is for example glued to the housing 13. In the example shown in Figure 1, the cover 15 and the bottom 14 each form a terminal of opposite polarity of the storage assembly 10. According to one variant, the outer casing 11 comprises a casing provided with a lateral wall and two covers each attached to one of the open ends of the casing along the longitudinal axis 12, and each forming a terminal of opposite polarity.

The outer casing 1 1 accommodates an electrical energy storage element 16, for example a supercapacitor or a battery. In the example shown in Figure 1, the storage element 16 forms a coil. It is said "coiled".

The storage element 16 comprises an elementary sequence 17 represented in FIG. 2.

The elementary sequence 17 comprises an elementary cell 18. The elementary cell 18 comprises a first electrode complex 19 and a second electrode complex 20 superimposed on one another in a superposition direction 21.

In the example shown in FIG. 2, the first and second electrode complexes 19 and 20 each comprise two electrodes 22 and 23 between which an electric current collector 24 and 25 is interposed. The electrodes 22 and 23 and the collector 24 or 25 are in one piece.

According to a variant not shown, the first and second electrode complexes comprise a single electrode and / or a single electrode with a current collector. In the case where the first and second complexes comprise a single electrode, the elementary cell may comprise a collector layer in addition to the electrode complex.

It will be noted that here identical electrode complexes 19 and 20 have been described at the two terminals of the elementary cell 18, but that the elementary cell 18 could very well be asymmetrically formed, for example comprising a first or a second one. electrode complex 19 or 20 as previously described and a second or a first electrode complex 20 or 19 composed a single electrode and a collector layer or having any other architecture.

The electrodes 22 and 23 are porous and impregnated with an electrolyte. The electrodes 22 and 23 are for example mainly made of activated carbon.

The first electrode complex 19 forms a first set of a first polarity connected to a first electrical terminal by means of the collector 24. The first terminal is for example formed by the cover 15 of the outer casing 11.

The second electrode complex 20 forms a second set of a second polarity connected to a second electrical terminal by means of the collector 25. The second terminal is of opposite polarity to the first terminal. The second terminal is for example formed by the bottom 14 of the outer casing 11.

The elementary cell 18 further comprises a first separator 26 disposed between the first electrode complex 19 and the second electrode complex 20. The first separator 26 is made of plastic, for example polypropylene, and electrically isolates the first and second complexes 19 and 20 between them, so as to avoid the generation of a short circuit in the storage element 16. The first separator 26 is porous so as to allow the ionic conduction between the first and second complexes of electrode 19 and 20.

The elementary sequence 17 further comprises a second separator 27 superimposed on the second electrode complex 20 of the elementary cell 18 in the superimposition direction 21.

The elementary sequence 17 is wound on itself around a winding axis 28, so as to form the coil. The winding axis 28 coincides with the longitudinal axis 12, when the storage element 16 is placed inside the outer casing 11. All the layers of the coil which are of the same nature are therefore in one piece, being constituted respectively by the same component of the elementary sequence. In other words, all the layers comprising the first electrode complex 19 are in one piece, and all the layers comprising the second electrode complex 20 are in one piece. Likewise, all the layers comprising the first separator 26 are in one piece, and all the layers comprising the second separator 27 are in one piece.

A sectional view of the coil is schematically shown in FIG.

As illustrated in FIG. 3, when the elementary sequence 17 is wound up, the first electrode complex 19 interacts with the second electrode complex 20 of the same winding turn n, but also with the second electrode complex 20 of the winding tower n-1. Similarly, the second electrode complex 20 interacts with the first electrode complex 19 of the same winding turn n, but also with the first electrode complex 19 of the winding revolution n + 1.

The collector 24 of the first electrode complex 19 and the collector 25 of the second electrode complex 20 project with respect to the electrode layers 22 and 23 in an opposite direction along the winding axis 28. In this way, the collector 24 of the first electrode complex 19 projects towards the first terminal 15 and the collector 25 of the second electrode complex 20 projects towards the second terminal 14, when the storage element 16 is positioned inside the the outer envelope 1 1. Thus, the connection of the collectors 24 and 25 to their respective terminals is easier.

The storage element 16 also comprises additional layers 29 and 30 respectively at each of the ends 31 and 32 of the storage element 16 in a radial direction. At a first radial end 31 disposed within the coil, the additional layers 29 are wound on themselves about the winding axis 28, so as to form a core around which the elementary sequence 17 is wound. At a second radial end 32 disposed outside the coil, the additional layers 30 are wound around the coil along the winding axis 28, so as to envelop it. Each additional layer 29 and 30 is constituted by a component identical to one of the components of the elementary cell 18. In other words, each additional layer 29 and 30 is chosen from the following components:

an electrode alone,

an electric current collector,

a single electrode and an electric current collector,

an electrode complex comprising two electrodes between which an electric current collector is interposed,

- a plastic separator.

Thus, the additional layers 29 and 30 are chosen from the components already available for the manufacture of the storage element 16.

The storage element 16 may comprise additional layers

29 and 30 identical or different to each radial end 31 and 32.

The storage element 16 may comprise the same number or a different number of additional layers 29 and 30 at each radial end 31 and 32.

The storage element 16 may also comprise additional layers 29 or 30 only at one of its radial ends 31 or 32.

In the example of Figure 3, some of the additional layers 29 and

Radial ends 31 and 32 are constituted by an electrode complex comprising two electrode layers between which a current collector is interposed. Because of the porosity of the electrodes, which therefore contain a lot of air, the electrode complexes constitute particularly effective heat shields. Since the collectors are already assembled with the electrodes before formation of the elementary cells, the electrode complex is used in its entirety to form the additional layers 29 and 30. In the example of FIG. 30 are constituted by a separator, which is an inexpensive material. In the example shown in FIG. 3, the storage element 16 comprises at the first radial end 31 two additional layers 29, including from the first radial end 31 towards the second radial end 32, an electrode complex and a separator. made of plastic The storage element 16 comprises at the second radial end 32 three additional layers 30, including two layers of plastic separator between which an electrode complex is interposed.

None of the additional layers 29 and 30 of the same radial end 31 and 32 are connected to the set of polarity opposite to the set of polarity to which is connected the electrode complex 19 or 20 of the elementary cell

18 adjacent to said additional layers.

In the example shown in FIG. 3, at the first radial end 31, the additional layers 29 are adjacent to the first electrode complex

19, connected to the first terminal 15. Thus, the additional layers 29 of the first radial end 31 can not be connected to the second terminal 14.

In the same way, at the second radial end 32, the additional layers 30 are adjacent to the second electrode complex 20 connected to the second terminal 14. Thus, the additional layers 30 of the second radial end 32 can not be connected to the first terminal 15.

In this way, there can be no short circuits either between the additional layers 29 and 30 of the same radial end 31 and 32 or between the additional layers 29 and 30 and the electrode complexes 19 and 20. of the elementary cell 18 adjacent to said additional layers. Furthermore, there can also be such short circuits when heating the storage element 16 and shrink additional layers 29 and 30 of plastic. The term "shrinkage" is understood to mean a deformation of the plastic separator layers 26 and 27 tending to expose the electrode layers 22 and 23 at their ends along the winding axis 28 and which can lead to an electrical contacting of two electrode layers 22 and 23 adjacent of opposite polarity and therefore to a short circuit in the storage element 16.

In addition, the additional layers 29 and 30 form a heat shield which makes it possible, when the storage element 16 is heated, to limit the shrinkage of the plastic separator layers 26 and 27 of the different elementary cells 18, and therefore of the reduce the risk of short circuits in the storage element 16.

According to a first embodiment, an additional layer 29 or 30 of a radial end 31 or 32 is connected to the terminal of the same polarity as the electrode complex 19 or 20 of the elementary cell adjacent to said additional layers. According to a second embodiment, an additional layer 29 or 30 of a radial end 31 or 32 is connected neither to the first terminal 15 nor to the second terminal 14.

It is ensured that this is indeed the case by conforming the electrode complexes constituting the additional layers 29 or 30 so that the collector protrudes on the same side as the collector 24 or 25 of the electrode complex 19 or 20 belonging to to the elementary cell 18 and adjacent to the additional layers 29 or 30. It can not therefore be connected to the terminal of opposite polarity, even by mistake.

Alternatively, it is possible to perform a step of treating the electrode complex of the additional layer 29 or 30 during which the portion of the collector protruding from the electrode is cut, in order to avoid any risk of contact with one two terminals 14 or 15.

The manufacture of the reeled storage element 16 proceeds according to the following method.

In a first step, the first electrode complex 19 and the first separator 26 are superimposed in the superimposition direction 21.

During a second step, they are wound alone, on at least one turn, around the winding axis 28, so as to form the core comprising at less an additional layer 29. The core is for example wound around a pin.

Preferably, the additional layer 29 closest to the first radial end 31 comprises an electrode, so that the additional layer 29 can not stick to the winding pin as may be the case if the additional layer 29 is a plastic separator.

In the example shown in FIG. 3, the first electrode complex 19 and the first separator 26 are chosen to form the additional layers 29 of the first radial end 31. The first electrode complex 19 and the first separator layer 26 are wound alone around the winding axis 28 on a lathe.

Then, in a third step, the second electrode complex 20 and the second separator 27 are stacked on the first separator 26 - already wound to form the core - in the superposition direction 21, so as to form the sequence elementary 17.

In a fourth step, all the layers of the elementary sequence 17 are wound together around the core, so as to form the coil.

During a fifth step, a part of the components of the elementary sequence 17 closest to the first end 33 of the elementary sequence 17 in the superimposition direction 21 is cut off, namely the first electrode complex 19 and the first separator 26, while the other part of the layers of the elementary sequence 17 is wound alone, on at least one turn, around the winding axis 28, so as to wrap the coil with at least one additional layer 30.

Note that the first separator 26 can be cut off relative to the first electrode complex 20 also cut before finishing the winding, so that it exceeds a few millimeters of the first electrode complex 20 to prevent shorts in case of shrink in a tangential direction relative to the coil. In the example shown in FIG. 3, the second electrode complex 20 and the second separator 27 are chosen to form the additional layers of the first radial end 31. The second electrode complex 20 and the second separator 27 are wound alone around the winding axis 28 on a lathe.

Finally, during a sixth step, the storage element 16 is put in place in the outer envelope January 1, and in a seventh step, the storage element 16 is electrically connected to the first and at the second electrical terminal 15 and 14, so that the first electrode complex 19 is connected to the first terminal 15, the second electrode complex 20 is connected to the second terminal 14, and none of the additional layers 29 and 30 located at a radial end 31 and 32 of the storage element 16 is connected to the polarity terminal 15 or 14 opposite to the polarity terminal to which the electrode complex adjacent to said additional layers 29 and 30 is connected. .

Figure 4 shows the storage element 16 according to another embodiment of the invention. In the example shown in FIG. 4, the storage element 16 is said to be "stacked".

In the remainder of the description, only the elements that differ from the embodiment shown in FIGS. 1 and 3 will be detailed.

The storage element 16 comprises a stack of several elementary sequences 17 in a stacking direction 35. The stacking direction 35 coincides with the superposition direction 21, when the elementary sequences 17 are stacked.

As illustrated in FIG. 4, when the elementary sequences 17 are stacked, the first electrode complex 19 of an elementary sequence 17 of a stack m interacts with the second electrode complex 20 of the elementary sequence 17 of the same stack m, but also with the second electrode complex 20 of the elementary sequence 17 of the stack m-1. Similarly, the second electrode complex 20 of an elementary sequence 17 of a stack m interacts with the first electrode complex 19 of the sequence elementary 17 of the same stack m, but also with the first electrode complex 19 of the elementary sequence 17 of the stack m + 1.

The collector 24 of the first electrode complex 19 and the collector 25 of the second electrode complex 20 of each elementary sequence 17 protrude with respect to the electrode layers 22 and 23 in an opposite direction, perpendicular to the superposition direction 21 . In this way, the collector 24 of the first electrode complex 19 projects towards the first terminal and the collector 25 of the second electrode complex 20 projects towards the second terminal, when the storage element 16 is positioned at the first terminal. inside an outer envelope. Thus, the connection of the collectors 24 and 25 to their respective terminals is easier.

The storage element 16 also comprises additional layers 29 and 30 respectively at each of the ends 31 and 32 of the stack in the stacking direction 35.

In the example shown in Figure 4, the storage element 16 comprises at the first end 31 in the stacking direction 35 three additional layers 29, including the first end 31 to the second end 32 in the direction of superposition 35, an electrode complex, a plastic separator and an electrode complex. The storage element 16 comprises at the second end 32 in the superposition direction 35 two additional layers 30, including from the second end 32 to the first end 31 in the superimposition direction 35, an electrode complex and a separator. plastic material.

As previously described, the electrode complexes forming the additional layers 29 and 30 are arranged so that the collector protrudes on the same side as in the electrode complex 19 or 20 of the elementary cell 18 adjacent to the additional layers 29 and 30. They can thus be connected to the same terminal 14 or 15 as said electrode complex of the elementary cell 18 or connected to any of the terminals 14 or 15 but can not be connected to the terminal of opposite polarity, which makes it possible to avoid short circuits. The manufacture of the stacked storage element 16 proceeds according to the following method.

During a first step, the first electrode complex 19, the first separator 26 and the second electrode complex 20 are stacked in the stacking direction 35, so as to form the elementary cell 18.

Then, the second separator 27 is stacked on the second electrode complex 20 in the stacking direction 35, during a second step, so as to form the elementary sequence 17.

The first and second steps are repeated several times, so as to form the stack of several elementary sequences 17.

In a third step, one or more additional layers

29 and 30 are stacked in the stacking direction 35 at the first end 31 and / or the second end 32 in the stacking direction 35.

According to one variant, the additional layers 29 of the first end 31 in the stacking direction 35 are stacked together before the first step. Then, during the first step, the first electrode complex 19, the first separator 26 and the second electrode complex 20 are stacked in the stacking direction 35 on the additional layers 29 of the first end 31.

Finally, during a fourth step, the storage element 16 is put in place in the outer envelope 11, and in a fifth step, the storage element 16 is electrically connected to the first and at the second electrical terminal 15 and 14, so that the first electrode complexes 19 are connected to the first terminal 15, the second electrode complexes 20 are connected to the second terminal 14, and that no additional layers 29 and

30 located at one end 31 and 32 of the storage element 16 is connected to the polarity terminal 15 or 14 opposite to the polarity terminal to which the electrode complex adjacent to said additional layers 29 and 30 is connected.

The storage elements 16 previously described have the advantage of being provided with the additional layers 29 and 30 which can not enter short circuit neither between them nor with the electrode complex 19 or 20 of the elementary cell 18 adjacent to said additional layers in case of shrinkage of the layers of plastic separator, and which form a heat shield limiting the shrinkage of the separator layers 26 and 27 of plastic material or elementary sequences 17 when heating the storage element 16.

Of course, the invention is not limited to what has been described in the examples illustrated in FIGS. 3 and 4:

the number and configuration of the additional layers 29 and / or 30 could notably not be in accordance with what has been described. The additional layers 29 and / or 30 could for example comprise the same components, or an additional layer 29 or 30 could be constituted by a single electrode without a collector or by a single collector,

the additional layers 29 and / or 30 could be present just at one end 31 or 32 of the storage element 26,

the storage element 16 could be constituted differently, for example the electrode complexes 19 and / or 20 could comprise only one electrode, a collector being attached to it outside the stack,

the mechanical structure of the storage assembly 10 could be different from what has been described,

- etc.

Claims

An electrical energy storage assembly (10) comprising:

an electrical energy storage element (16) comprising at least one elementary cell (18) comprising a first and a second electrode complex (19, 20) superimposed in a superposition direction (21), said elementary cell comprising in addition to a first plastic separator (26) extending between the first and second electrode complexes,

an outer envelope (1 1) accommodating the storage element (16), the envelope comprising two distinct electrical terminal surfaces (15, 14) of the assembly having an opposite polarity, the first complex or complexes (19) being electrically connected to a first terminal (15) and the at least one complex (20) being electrically connected to a second terminal (14),

the assembly being characterized in that the element comprises at least one additional layer (29, 30) extending to at least one end (31, 32) of the storage element in the superposition direction, each additional layer being constituted by a component identical to one of the components (19, 20, 26, 27) of the elementary cell (18), none of the additional layers of the same end of the storage element being connected to the polarity terminal opposite the terminal to which the electrode complex adjacent to said additional layers is connected.

The storage assembly of claim 1, wherein the or at least one of the additional layers (29, 30) comprises an electrode (22, 23).

3. Storage assembly according to any one of claims 1 and 2, wherein the or at least one of the elementary cells (18) is provided with at least one collector (24, 25) for connecting a complex d the electrode (19, 20) of the cell to the corresponding terminal (15, 14), the or at least one of the additional layers (29, 30) having a collector (24, 25).

A storage assembly according to claims 2 and 3 in combination, wherein the or at least one of the additional layers (29, 30) is an electrode complex (19, 20) having at least one electrode (22, 23) and a collector (24, 25) in one piece.

A storage assembly (16) according to any one of claims 1 to 4, wherein the or at least one additional layer (29, 30) comprises a separator (26, 27) of plastics material.

Storage assembly according to one of the preceding claims, comprising at least one of the ends (31, 32) three adjacent additional layers (29) formed of two layers comprising an electrode between which a separator layer is interposed.

A storage assembly according to any one of claims 2 to 4, wherein at at least one end of the element at least one additional layer (29, 30) having an electrode is connected to the terminal of the same polarity as the electrode complex (19, 20) adjacent to the additional layers of said end.

A storage assembly according to any one of the preceding claims, wherein at least one additional layer (29, 30) of one of the ends (31, 32) is connected neither to the first nor to the second terminal (15, 14).

A storage assembly according to any one of the preceding claims, wherein the components (19, 20, 26, 27) of the at least one elementary cell (18) form stacked flat layers, the at least one additional layer (29, 30) being placed at one and / or the other end (31, 32) of the stack.

The storage assembly of any one of claims 1 to 8, wherein the components (19, 20, 26, 27) of the at least one elementary cell (18) are wound so that a single component forms a plurality of layers of the winding and that the element (16) has a coil shape, the additional layer or layers (29, 30) being placed inside and / or outside the winding.

1 1. An assembly according to claim 10, wherein the additional layer (29) located furthest inside the coil is a layer having an electrode (22) and / or a collector (24).

12. An assembly according to any one of the preceding claims, wherein at least one of the additional layers (29, 30) is made using a component (19, 20, 26, 27) also forming at least a layer of the or at least one of the elementary cells (18).

A method of manufacturing an electrical energy storage assembly (10), comprising the following steps of:

superposition of a first electrode complex (19), a first separator (26), and a second electrode complex (20) in a superposition direction (21) so as to form a cell elementary (18);

- Realizing the storage element (16) from at least one elementary cell (18) and at least one additional layer (29, 30) constituted by a component identical to one of the components of the elementary cell, so that the additional layer or layers are placed at the end (31, 32) of the storage element;

- placing the storage element (16) in an outer envelope (1 1) and electrically connecting the storage element to electrical terminals (14, 15) of opposite polarity of the storage assembly, formed by two distinct surfaces of the envelope, so that the at least one complex (19) is electrically connected to a first terminal (15) and the at least one complex (20) is connected to a second terminal (14) and none of the additional layers (29,

30) at one end (31, 32) of the storage element is connected to the terminal of polarity opposite to the polarity terminal to which the electrode complex adjacent to said additional layers is connected.

The method of claim 13, comprising the steps of:

superimposing a second separator (27) on the second electrode complex (20) in the superposition direction (21), so as to form an elementary sequence (17);

winding the elementary sequence around a winding axis

(28), so that the storage element (16) has a coil shape.

The method of claim 14, wherein a portion of the components (19, 26) of the elementary sequence (17) is wound alone around the winding axis (28), so as to form a core of at least one additional layer (29) around which the elementary sequence is then wound.

The method of claim 15, wherein two components consisting of the first electrode complex (19) and the first separator (26) are wound alone around the winding axis (28), so as to form the core of at least one additional layer (29).

The method of any one of claims 14 to 16, wherein a portion of the components (20, 27) of the elementary sequence (17) is wound alone around the winding axis (28), so that wrapping at least one additional layer (30) the coil comprising the elementary sequence (17).

The method of claim 17, wherein the second electrode complex (20) and the second separator (27) are wound alone around the winding axis (28) so as to envelop the coil of at least an additional layer (30).

The method of claim 13, comprising the steps of:

superposition of a second separator (27) on the second electrode complex (20) in a stacking direction (35) coincident with the superposition direction (21), so as to form an elementary sequence (17);

stacking of several elementary sequences according to the stacking direction;

stacking at least one additional layer (29, 30) with at least one elementary sequence so that the additional layer or layers (29, 30) are located at at least one end (31, 32) of the stack previously formed according to the stacking direction.